CN211168672U

CN211168672U - Spiral conveyer

Info

Publication number: CN211168672U
Application number: CN201921463764.9U
Authority: CN
Inventors: 洪健荣
Original assignee: Shenzhen New South China Sea Transmission Machinery Co Ltd
Current assignee: South China Xinhai (Shenzhen) Technology Co.,Ltd.
Priority date: 2019-09-04
Filing date: 2019-09-04
Publication date: 2020-08-04
Anticipated expiration: 2029-09-04
Also published as: WO2021042452A1

Abstract

The utility model discloses a screw conveyer, include: the pillar is vertically erected on a base of the conveyor; the chain plate frame is spirally wound outside the support column, one end of the chain plate frame close to the bottom of the support column extends outwards to form a first conveying port, and one end of the chain plate frame close to the top of the support column extends outwards to form a second conveying port; the return bracket is vertically erected on one side of the chain plate frame, the bottom of the return bracket is communicated with the first material conveying opening, and the top of the return bracket is communicated with the second material conveying opening; the conveying chain is arranged on the chain plate frame, one end part of the conveying chain enters the return support through the conveying port II and is connected with the other end of the conveying chain through the conveying port I to form an annular conveying chain; and the power mechanism is linked with the transmission chain and drives the transmission chain to circularly run along the chain plate frame and the return bracket. The utility model discloses simple structure transports the eminence with the goods through the spiral mode in finite space, improves freight efficiency.

Description

Spiral conveyer

Technical Field

The utility model relates to a transmission equipment field especially relates to a screw conveyer.

Background

At present, goods are usually transferred by adopting a conveying belt in the transportation of the goods, but because the space of a factory building on site is limited, a common conveying belt can only connect a plurality of sections of conveying belts in a turning splicing mode, and thus the transportation path of the goods is increased in the limited space. However, the conveyer belts connected in a turning splicing manner still transport the goods in the same horizontal direction, and still occupy a large amount of space of the plant, so that the interior of the plant is crowded, and the space utilization rate is low; furthermore, in order to transport the cargo to a high place, the cargo is generally transported by using a lift, but the lift needs to be lifted and lowered back and forth when the cargo is loaded and unloaded, and thus the transport efficiency cannot be improved.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a screw conveyer transports goods to eminence, make full use of indoor space and then improve the goods transport efficiency through the spiral mode in the finite space.

The purpose of the utility model is realized by adopting the following technical scheme:

a screw conveyor comprising:

a pillar, which is vertically erected on the base of the conveyor;

the chain plate frame is spirally wound outside the support column, one end of the chain plate frame close to the bottom of the support column extends outwards to form a first conveying port, and one end of the chain plate frame close to the top of the support column extends outwards to form a second conveying port;

the return bracket is vertically erected on one side of the chain plate frame, the bottom of the return bracket is communicated with the first material conveying opening, and the top of the return bracket is communicated with the second material conveying opening;

the conveying chain is arranged on the chain plate frame, one end part of the conveying chain enters the return support through the conveying port II and is connected with the other end of the conveying chain through the conveying port I to form an annular conveying chain;

and the power mechanism is linked with the transmission chain and drives the transmission chain to circularly run along the chain plate frame and the return bracket.

Furthermore, the inner side and the outer side of the chain plate frame are provided with guardrails.

Furthermore, the extending directions of the first material conveying port and the second material conveying port are the same.

Furthermore, the bottom end of the return support extends to a first material conveying port in a mode of surrounding the support and then is connected with the first material conveying port.

Further, power unit includes motor, driving gear axle and driven gear axle, driving gear axle sets up the one end at the chain grillage, and the driven gear axle sets up the other end at the chain grillage, and transmission chain cover is established on driving gear axle and driven gear axle, and the motor is connected with the driving gear axle.

Further, the driving gear shaft and the driven gear shaft are identical in structure and comprise a rotating shaft and a plurality of gears, the gears are evenly sleeved on the rotating shaft, and the motor drives the rotating shaft to rotate so that the gears are meshed with the transmission chain and synchronously drive the transmission chain to run.

Furthermore, the transmission chain is provided with a modular conveying net belt, the lower surface of the modular conveying net belt is provided with grooves matched with the gears on the driving gear shaft, and teeth of the gears of the driving gear shaft are meshed with the grooves to drive the transmission chain to operate.

Further, an anti-slip layer is arranged on the surface of the conveying chain, which is in contact with the goods.

Further, the inner side edge of the chain plate frame close to the support column is connected with the surface of the support column through a connecting rod.

Compared with the prior art, the beneficial effects of the utility model reside in that:

(1) the chain plate frame surrounds the pillars in a spiral shape, plays a role of mainly supporting a transmission chain, can increase the transportation path of goods, continuously transports the goods to a high place, fully utilizes limited space and improves the transportation efficiency;

(2) the upper end of chain plate frame is connected with the lower extreme of chain plate frame through the return stroke support, for the transmission chain provides circulation downstream's return stroke route, provides the holding power for the chain plate frame that is in the eminence simultaneously, reduces the goods of transporting the eminence and produces too big downward extrusion force to the chain plate frame of spiral formula to improve spiral conveyer's whole steadiness.

Drawings

Fig. 1 is one of the schematic structural diagrams of the present invention;

fig. 2 is a second schematic structural diagram of the present invention;

fig. 3 is a schematic structural diagram of the driving gear shaft of the present invention.

In the figure: 1. a pillar; 2. a chain plate rack; 201. a first material conveying port; 202. a material conveying port II; 3. a return bracket; 4. a base; 5. a driving gear shaft; 501. a motor; 502. a rotating shaft; 503. a gear; 6. a driven gear shaft; 7. a support rod.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

A screw conveyer transports goods to different horizontal heights in a screw mode, fully utilizes limited space and improves goods transportation efficiency.

The spiral conveyor comprises a pillar 1, a chain plate frame 2 and a return bracket 3. As shown in fig. 1 and 2, the support column 1 is vertically erected on a base 4 of the conveyor; the outside of the pillar 1 is spirally wound with a chain plate frame 2, and the chain plate frame 2 plays a role of mainly supporting a transmission chain; in order to improve the bearing force of the chain plate frame 2, a support rod 7 is arranged on the bottom surface of the chain plate frame 2, and the support rod 7 extends towards the support column 1 and is fixed on the support column 1, so that the chain plate frame 2 is more stable in the process of transporting heavy objects.

One end of the chain plate frame 2 close to the bottom of the strut 1 extends outwards to form a first material conveying opening 201, the first material conveying opening 201 can be connected with a common linear conveying belt, and goods conveyed in place by the linear conveying belt are directly conveyed into the spiral chain plate frame 2 for conveying; and one end of the chain plate frame 2 close to the top of the pillar 1 extends outwards to form a second material conveying opening 202, and the second material conveying opening 202 can be connected with a linear conveying belt.

The extending directions of the first material conveying port 201 and the second material conveying port 202 can be adjusted according to actual transportation conditions, and the extending directions of the first material conveying port 201 and the second material conveying port 202 are the same in the embodiment, so that goods can be fed from one direction and can be discharged from the same direction, and space can be further saved.

And the side edge of the pillar 1 is assembled with a return bracket 3, one end of the return bracket 3 is communicated with a second material conveying opening 202 of the chain plate frame 2, and the other end of the return bracket 3 extends to a first material conveying opening 201 in a mode of surrounding the pillar 1 and then is connected with the first material conveying opening 201, so that a return path is provided for a transmission chain.

The chain plate frame 2 is provided with a transmission chain, the transmission chain is connected with a power mechanism, and the power mechanism drives the transmission chain to rotate upwards or downwards along the chain plate frame 2. One end of the transmission chain enters the return support 3 through the second material conveying port 202 and is connected with the other end of the transmission chain through the first material conveying port 201, so that the head of the transmission chain is connected to form an annular transmission chain.

And power unit is including motor 501, driving gear shaft 5 and driven gear shaft 6, driving gear shaft 5 sets up the one end at link plate frame 2, and driven gear shaft 6 sets up the other end at link plate frame 2, and in this embodiment, driving gear shaft 5 sets up the one end that is close to 1 bottom of pillar at link plate frame 2, and driven gear shaft 6 then sets up the one end near 1 top of pillar, and driving gear shaft 5 sets up and can be convenient for at the low and be connected with motor 501, avoids motor 501 to install and makes the link plate frame 2 that is located the eminence bear a burden and influence the overall stability of link plate frame 2 at the eminence.

The driving gear shaft 5 and the driven gear shaft 6 have the same structure, and as shown in fig. 3, include a rotating shaft 502 and a plurality of gears 503, the plurality of gears 503 are evenly sleeved on the rotating shaft 502, and the motor 501 drives the rotating shaft 502 to rotate so that the plurality of gears 503 rotate synchronously; when the transmission chain is sleeved on the driving gear shaft 5 and the driven gear shaft 6, the plurality of gears 503 are meshed with the transmission chain to drive the transmission chain to operate. In this embodiment, the transmission chain is provided with a modular transmission mesh belt, the modular transmission mesh belt is formed by splicing a plurality of connecting modules, the lower surface of each connecting module is provided with a plurality of grooves which are matched with the plurality of gears 503 on the driving gear shaft 5, the plurality of gears 503 on the driving gear shaft 5 are meshed with the grooves of the connecting modules, and the transmission chain is driven to integrally operate while the driving gear shaft 5 rotates. When the rotation direction of the motor 501 is changed, the running direction of the transmission chain can be changed, so that the transmission chain can realize bidirectional transportation.

Because link plate frame 2 extends to the eminence from the low department with the spiral mode, in order to avoid being located link plate frame 2 of eminence to extrude link plate frame 2 that is located the low department because of gravity and cause link plate frame 2 to appear the phenomenon of splitting, link plate frame 2 can be made to the establishment of return stroke support 3, has further improved link plate frame 2's stability.

When goods are transported along the spiral chain plate frame 2, a certain centrifugal force exists in the transportation process of the goods, so that the goods are prevented from falling off the chain plate frame 2 due to the deviation of the centrifugal force, and guardrails are arranged on the inner side and the outer side of the chain plate frame 2; meanwhile, the spiral transmission chain has a certain inclination angle, so that an anti-skid layer is arranged on the surface of the transmission chain contacting with the goods, the friction force between the goods and the transmission chain is increased, and the slipping phenomenon when the goods rise or fall along the transmission chain is avoided, so that the goods are stacked to influence the normal transmission process.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims

1. A screw conveyor, comprising:

a pillar, which is vertically erected on the base of the conveyor;

2. The screw conveyor according to claim 1, wherein guard rails are provided on both inner and outer sides of the chain plate frame.

3. The screw conveyor of claim 1, wherein the first material conveying opening and the second material conveying opening extend in the same direction.

4. The screw conveyor of claim 2, wherein the bottom end of the return leg extends around the post to a first material port and then connects to the first material port.

5. The screw conveyor of claim 1, wherein the power mechanism comprises a motor, a driving gear shaft and a driven gear shaft, the driving gear shaft is arranged at one end of the chain plate frame, the driven gear shaft is arranged at the other end of the chain plate frame, the transmission chain is sleeved on the driving gear shaft and the driven gear shaft, and the motor is connected with the driving gear shaft.

6. The screw conveyor according to claim 5, wherein the driving gear shaft and the driven gear shaft are identical in structure and each include a rotating shaft and a plurality of gears, the plurality of gears are uniformly sleeved on the rotating shaft, and the motor drives the rotating shaft to rotate so that the plurality of gears engage with the transmission chain and synchronously drive the transmission chain to operate.

7. The spiral conveyor as claimed in claim 1, wherein the transmission chain is provided with a modular conveyor belt, the lower surface of the modular conveyor belt is provided with grooves matched with the plurality of gears on the driving gear shaft, and teeth of the plurality of gears on the driving gear shaft are engaged with the grooves to drive the transmission chain to operate.

8. The screw conveyor according to claim 1, wherein a surface of the conveyor chain contacting the cargo is provided with an anti-slip layer.

9. A spiral conveyor as in claim 1 wherein the inside edges of the chain plate frames adjacent the posts are connected to the post surfaces by connecting rods.